Global ETD Search

11	Smoothened regulation in the Hedgehog signaling pathway Nedelcu, Daniel 18 October 2013 (has links) Hedgehog signaling is a pathway essential in embryonic development, adult stem cell maintenance, and is implicated in the formation and progression of cancer. Signaling in this pathway is triggered when the secreted protein Hedgehog binds to its membrane receptor, Patched. Patched normally inhibits the seven-spanner transmembrane protein Smoothened (Smo). Binding of Hedgehog inhibits Patched resulting in Smo derepression. Active Smo then triggers the activation of the cytoplasmic steps of the signaling pathway. Cellular biology Chemistry Biology cilium cysteine-rich domain Hedgehog oxysterols Smoothened
12	Regulation of Inverted Formin-1 (INF1) by Microtubule-Affinity Regulating Kinase 2 (MARK2) Kulacz, Wojciech 30 April 2012 (has links) The actin and microtubule cytoskeleton plays a critical role in the establishment of cell polarity. Cell processes like mitosis and migration rely on the reorganization of the cytoskeleton to properly function. One driver of cell polarity is the formin, Inverted Formin-1 (INF1). INF1 is able to induce F-actin formation, activate the Serum Response Factor (SRF) pathway, stabilize microtubules, associate with microtubules, and disperse the Golgi body. Regulation of INF1 is unique, since it does not possess conserved formin regulatory domains. However, INF1 does possess many potential phosphorylation sites. In this study, we demonstrate that INF1’s ability to induce F-actin stress fibers and activate SRF is inhibited by Microtubule-Affinity Regulating Kinase 2 (MARK2). Inhibition of INF1’s actin polymerization activity by MARK2 likely occurs near INF1’s C-terminus. However, MARK2 was unable to inhibit INF1’s ability to stabilize microtubules, associate with microtubules, and disperse the Golgi. Furthermore, we show that INF1 overexpression is associated with primary cilium absence and in some cases, the presence of long cilia, suggesting that INF1 plays a role in primary cilium formation. formins Inverted Formin-1 (INF1) actin microtubules primary cilium
13	Rôle du cil primaire au cours de la différenciation adipocytaire / Role of the primary cilium during adipocyte differentiation Forcioli-Conti, Nicolas 15 December 2015 (has links) Le cil primaire (CP) est une organelle présente chez l’Homme dans la grande majorité des cellules. Lors du développement le CP est d’une importance capitale, puisqu’il contrôle les voies de signalisation comme Hedgehog ou Wnt. Certaines pathologies génétiques affectant spécifiquement le CP, engendrent une obésité. Au cours de ma thèse je me suis intéressé à l’évolution du CP au cours de l’adipogenèse des cellules souches mésenchymateuses humaines. Les résultats que nous avons obtenus indiquent que le cil est présent dans les cellules indifférenciées, qu’il subit une élongation importante suite à l’induction de la différenciation, suivi d’une diminution de sa taille et fini par disparaitre dans les adipocytes. L’élongation de la taille du cil ne semble pas affecter la localisation des protéines qui lui sont associées comme Kif3-A ou Smoothened, une protéine importante de la voie Hedgehog. Néanmoins, il apparait que la voie de signalisation Hedgehog est inhibée après trois jours de différenciation et que les cellules ont développé une résistance à Sonic Hedgehog. La déacétylase de la tubuline acétylée HDAC6 est apparue comme étant une bonne cible puisque son expression augmente au cours de la différenciation et qu’elle est décrite pour être responsable de la perte du cil pendant la mitose. Les données que nous avons obtenues ont permis de montrer que l’inhibition, ou la surexpression d’HDAC6 au cours de l’adipogenèse engendrent une inhibition de l’élongation du cil associée à une forte inhibition de la différenciation adipocytaire. Ces résultats permettront, à terme de mieux comprendre les liens entre le cil primaire et la différenciation adipocytaire. / The primary cilium (PC) is an organelle present in almost all cell types of the organism. During development, the PC plays an important function by driving signaling pathways such as Hedgehog or Wnt. Some genetic syndromes affecting specifically the PC are associated with obesity. My project has consisted to analyze the evolution of the PC during adipocyte differentiation of human mesenchymal stems cells. Our results indicate that the PC is present in undifferentiated cells, then it undergoes a strong elongation at the beginning of the differentiation followed by a decreased of its size, and disappears in differentiated cells. This increase in the cilium size does not affect the localization of its associated proteins such as KIF3-A and Smoothened an important protein of the Hedgehog signaling pathway. However, this pathway is inhibited after three days of differentiation and cells have developed a Sonic Hedgehog resistance. The tubulin deacetylase HDAC6 appeared as a good target because its expression increases during differentiation and it is known to be responsible for the loss of the cilium during mitosis. Our data show that an inhibition or an overexpression of HDAC6 lead to a decrease in the cilium elongation associated with an inhibition of adipocyte differentiation. These results will ultimately lead to a better understanding of the connections between the PC and adipocyte differentiation. Cil primaire Différenciation adipocytaire Hedgehog HDAC6 Primary cilium Adipocyte differentiation Hedgehog HDAC6
14	Caractérisation fonctionnelle du complexe LKB1/STRADß au cil primaire et les conséquences au cours de la tumorigenèse / Functional characterization of LKB1/Stradβ complex in the primary cilia and the consequences during tumorigenesis Maurin, Pauline 14 December 2016 (has links) Des mutations du gène STK11 furent initialement décrites comme responsable du syndrome Peutz-Jeghers, dont la gravité est lliée à une incidence accrue d’apparition de tumeurs. Le produit de ce gène, la sérine/thréonine kinase LKB1, a une expression ou une activité catalytique réduite, voir perdue, consécutivement à des mutations somatiques dans plusieurs types de cancer mais principalement du poumon (30% des NSCLC). Cette kinase est considérée de ce fait comme un suppresseur de tumeur d’importance. Les mécanismes moléculaires responsables de sa propriété suppresseur de tumeur restent à identifier. En effet, alors que sa fonction dans le métabolisme cellulaire, au travers de l’activation de la kinase AMPK, fut longtemps privilégiée, elle est actuellement remise en cause au profit de sa fonction de régulatrice de la signalisation Wnt canonique. Mes travaux de thèse confortent cette éventualité dans le cas des tumeurs pulmonaires (NSCLC). En effet, parmi les deux complexes fonctionnels que forme LKB1 avec les pseudokinases STRADα ou β, mes résultats démontrent que seul celui impliquant STRADβ intervient dans la régulation de la voie Wnt. Pour cela, le complexe LKB1/STRADβ se localise au niveau du cil primaire et participe à l’activation de la kinase MARK3. Ces résultats, étayés par un modèle murin invalidé pour STRADβ ainsi que l’analyse, a posteriori, de bases de données transcriptomiques adossées aux données cliniques de patients atteints de NSCLC, suggèrent que l’activité suppresseur de tumeur de LKB1 est associée à sa localisation et à sa fonction au niveau du cil primaire en participant à l’activation de MARK3 et à la régulation de la signalisation Wnt canonique. / STK11 gene mutations were originally identified as responsible for the Peutz-Jeghers syndrome of which severity is mainly related to an increase incidence of tumor development. The product of this gene the serine/threonine kinase LKB1 gets its activity or its expression reduced, sometimes even lost, following somatic mutations in several types of cancer such as pancreas, liver but mainly from lung. Indeed, almost 30% of non-small cell lung carcinoma (NSCLC) does not express anymore or only an inactive form, has led to consider this kinase as tumor suppressor of importance. While there is no doubt of the involvement of its catalytic activity molecular mechanisms responsible for its tumor suppressor properties remain to be identified. Indeed, whereas its function as regulator of cellular metabolism through AMPK has been favor for a while, it is currently re-assess to benefit to its regulator function on canonical Wnt signaling. My thesis work, reinforce this eventuality in NSCLC. Indeed, among the two functional complexes formed by LKB1 through its association with STRADα or β pseudokinases, my results show that only the complex related to STRADβ is involved in the canonical Wnt pathway regulation. For that, LKB1/STRADβ complex localizes at primary cilia and participates to MARK3 kinase activation. These results strengthened by a STRADβ knockout mouse model and an a posteriori transcriptomic analysis of lung adenocarcinoma patient datasets related to their clinical records, suggest that LKB1 tumour suppressor activity is associated with its localization and its function at primary cilia participating in the activation of MARK3 and thus regulation of canonical Wnt signaling. LKB1/STRADb Cil primaire Signalisation Wnt canonique Nsclc LKB1/STRADb Primary cilium Canonical Wnt signaling Nsclc
15	Regulation of Inverted Formin-1 (INF1) by Microtubule-Affinity Regulating Kinase 2 (MARK2) Kulacz, Wojciech January 2012 (has links) The actin and microtubule cytoskeleton plays a critical role in the establishment of cell polarity. Cell processes like mitosis and migration rely on the reorganization of the cytoskeleton to properly function. One driver of cell polarity is the formin, Inverted Formin-1 (INF1). INF1 is able to induce F-actin formation, activate the Serum Response Factor (SRF) pathway, stabilize microtubules, associate with microtubules, and disperse the Golgi body. Regulation of INF1 is unique, since it does not possess conserved formin regulatory domains. However, INF1 does possess many potential phosphorylation sites. In this study, we demonstrate that INF1’s ability to induce F-actin stress fibers and activate SRF is inhibited by Microtubule-Affinity Regulating Kinase 2 (MARK2). Inhibition of INF1’s actin polymerization activity by MARK2 likely occurs near INF1’s C-terminus. However, MARK2 was unable to inhibit INF1’s ability to stabilize microtubules, associate with microtubules, and disperse the Golgi. Furthermore, we show that INF1 overexpression is associated with primary cilium absence and in some cases, the presence of long cilia, suggesting that INF1 plays a role in primary cilium formation. formins Inverted Formin-1 (INF1) actin microtubules primary cilium
16	Stabilita proteinových komplexů cytoskeletu eukaryotického bičíku / Stability of protein complexes in the cytoskeleton of the eukaryotic flagellum Pružincová, Martina January 2019 (has links) The cilium/flagellum is a complex organelle protruding from the cell body and functioning in motility, sensing, and signalling. It is composed of hundreds of protein constituents, the majority of which comprise the flagellar cytoskeleton - the microtubule-based axoneme. Because the flagellum lacks ribosomes, its protein constituents have to be imported from the cell body and delivered to proper locations. Moreover, these proteins have to retain their function over a considerable length of time, despite the mechanical stress caused by flagellar beating and due to environmental exposure. This raises the question whether and where protein turnover occurs. Previously, it was established that Chlamydomonas reinhardtii flagella are dynamic structures (Marshall & Rosenbaum, 2001). In contrast, in the Trypanosoma brucei flagellum axonemal proteins are remarkably stable (Vincensini et al., 2018). However, the questions of axonemal assembly and stability were so far investigated only for a small number of proteins and during relatively short periods. Moreover, in these experiments expression of studied proteins was controlled by non-native regulatory elements. To elucidate the site of incorporation of proteins from all major axonemal complexes and to find out if and where the protein turnover occurs, T....
17	Examining the Regulation and Functions of Centrosomal Mps1 Marquardt, Joseph R. 11 August 2017 (has links) No description available. Molecular Biology Cellular Biology Genetics Biology Mps1 cell cycle centrosome centriole kinetochore primary cilium cell biology
18	Ciliogenesis Control Mechanisms in Cerebellar Neuron Progenitors / Contrôle de la ciliogenèse des progéniteurs des neurones du cervelet Zanini, Marco 05 December 2019 (has links) Pendant le développement du cervelet, les progéniteurs des neurones granulaires (PNG) nécessitent la présence du cil primaire pour proliférer en réponse à Sonic Hedgehog (SHH). En effet, la prolifération dérégulée des PNGs peut conduire à la formation d'une tumeur pédiatrique maligne appelée SHH-médulloblastome (MB), de ce fait comprendre comment le cil primaire est régulé dans les PNGs est crucial.Nous montrons que le facteur de transcription Atoh1 contrôle la présence du cil primaire dans les PNGs in vitro et in vivo. En particulier, la suppression du cil primaire par l’inactivation génétique de gènes impliqués dans la ciliogenèse (par exemple, Kif3a ou Ift88) empêche Atoh1 de maintenir les PNGs en prolifération, ce qui indique qu’Atoh1 favorise l’expansion des PNGs en maintenant la présence du cil primaire. D’un point de vue moléculaire, Atoh1 contrôle la formation du cil primaire en régulant le bon positionnement peri-centrosomal des satellites centriolaires (SC), complexes protéiques essentiels pour la ciliogenèse. L'inactivation de Atoh1 dans les PNGs perturbe en effet la distribution subcellulaire des SCs, altérant ainsi inévitablement la ciliogenèse. Cette nouvelle fonction de Atoh1 est gouvernée par la régulation transcriptionnelle directe d'un composant clé des SCs, Cep131. L’expression ectopique de Cep131 dans les PNGs restore les effets liés à l'inactivation d'Atoh1, rétablissant la localisation correcte du SC et comme conséquence la présence d’un cil primaire.De plus, nous avons montré que cette voie Atoh1-SC-cil primaire-SHH contrôlant la prolifération des PNGs est également conservée dans le contexte du SHH-MB, où Atoh1 est surexprimée et essentielle pour sa formation et sa maintenance.Ces données révèlent un mécanisme par lequel la ciliogenèse est régulée dans des progéniteurs de neurones, offrant de nouvelles informations sur la neurogenèse dans le cervelet et sur la pathogenèse du SHH-MB. / Cerebellar granule neuron progenitors (GNPs) require the primary cilium to proliferate in response to Sonic Hedgehog (SHH) during cerebellar development. As aberrant proliferation of GNPs may lead to SHH-type medulloblastoma (SHH-MB), a pediatric brain tumor, understanding which mechanisms control ciliogenesis in GNPs represents a major interest in the field. Here, we show that the proneural bHLH transcription factor Atoh1 controls the presence of primary cilia in GNPs both in vitro and in vivo, thus maintaining GNPs responsive to the mitogenic effects of SHH. Indeed, loss of primary cilia induced via knockdown of specific ciliary components (e.g. Kif3a and Ift88) abolishes the ability of Atoh1 to keep GNPs in proliferation in vivo. Mechanistically, Atoh1 controls ciliogenesis by regulating the proper peri-centrosomal clustering of centriolar satellites (CS), large multiprotein complexes working as essential machineries for ciliogenesis. Knockdown of Atoh1 in GNPs perturbs CS subcellular distribution, leading to impairment of ciliogenesis. Luciferase reporter assays and chromatin immunoprecipitation experiments indicate that Atoh1 can directly regulate the expression of Cep131, a key CS core component. Importantly, ectopic expression of Cep131 in GNPs depleted of Atoh1, is sufficient to restore proper CS localization and consequent primary cilia formation, indicating that the Atoh1-Cep131-CS axis is responsible for ciliogenesis in GNPs.In addition, we further demonstrated that these functions of Atoh1 are conserved in the context of SHH-MB, where Atoh1 is typically overexpressed and acts as a lineage-dependent transcription factor.These data reveal a mechanism whereby ciliogenesis is regulated in neuron progenitors providing novel insights into cerebellar neurogenesis and pathogenesis of SHH-MB. Cervelet Médulloblastome Atoh1 Cil Primaire Cep131 Sonic Hedgehog Cerebellum Medulloblastoma Atoh1 Primary Cilium Cep131 Sonic Hedgehog
19	Primary Cilium in Bone Growth and Mechanotransduction Mariana Moraes de Lima Perini (11804414) 07 January 2022 (has links) <p>Bone loss diseases, including osteoporosis affect millions of people worldwide. Understanding the underlying mechanisms behind bone homeostasis and adaptation is essential to uncovering new therapeutic targets for the prevention and treatment of bone loss diseases. Primary cilia have been implicated in the development and mechanosensation of various tissue types, including bone. The goal of the studies outlined in this thesis is to determine the mechanosensory role of primary cilia in bone cell function, bone growth, and adaptation. This goal was achieved by exploring two specific scenarios. In the first study, mice models with conditional knockouts of MKS5, a ciliary protein, in osteocytes were utilized to demonstrate that dysfunctional primary cilia in those cells result in impaired loading-induced bone formation. The hypothesis tested is that the existence of functioning primary cilia on osteocytes is crucial for proper bone adaptation following stress. The results of this study support the hypothesis, with the conditional knockout mice showing significantly lower loading-induced bone formation compared to controls. The second study highlighted the importance of the osteoblast primary cilia in bone growth by using mice models with osteoblast-specific deletion of the cilia. The hypothesis tested is that the presence of the primary cilia is crucial for proper bone growth. The results show that conditional knockout mice have lower body weights, decreased femur length, and a significantly lower rate of bone formation, confirming that the primary cilia play a great role in bone growth and development. This study has highlighted the role of primary cilia in bone health and this topic merits further investigation. </p> Cell Biology Molecular Biology mechanotransduction bone primary cilia cilium osteocytes osteoblasts Ift88 MKS5 IFT proteins
20	GFAP Polarity and Primary Cilia in Astrocytes of Mouse Brain Elliott, Jonathan David 05 1900 (has links) Often in front-back, left-right, and top-bottom, cell polarity is a basic property of tissues and organs and essential for the development of multicellular organisms. In the central nervous system, neurons are a paragon of polarity, receiving action potentials in their apically located dendrites and propagating them down a single axon extending from the basal pole of neuronal somas, ultimately ending in basally situated axon termini. In contrast, astrocytes are often considered relatively unpolarized, in keeping with the meaning of their name, "star cells." However, astrocytes do exhibit polarity in the distribution of glial fibrillary acidic protein (GFAP) and the location of the primary cilium. These features may be polarized beginning with the birth of astrocytes, when newly born pairs of daughter cells are mirror images of each other with the most distant somatic poles having both the primary cilium and the highest concentration of GFAP. The present study is a systematic analysis which addresses these aspects of astrocyte polarity: heterogeneity across brain regions and ages; influence of cilium deficiency; and orientation with respect to brain architecture and migration. Cell polarity astrocyte GFAP primary cilium development neuroscience Biology, Neuroscience Biology, Cell Biology, General

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